Cold Spring Harbor, N.Y. – Scientists at Cold Spring Harbor Laboratory have identified a candidate drug target for treating acute myeloid leukemia (AML), a white blood cell cancer that proliferates out of control in the bone marrow. The team, led by Assistant Professor Chris Vakoc, M.D., Ph.D., shows that blocking a protein called PRC2 halts this uncontrolled proliferation in the bone marrow of mice with AML.

Unlike mice in which PRC2 is active (top), mice in which PRC2 activity is blocked with shRNA (bottom) show impaired progression of leukemia (red and blue patches).PRC2, short for Polycomb Repression Complex 2, is a chromatin regulator – a type of protein that alters the way genes are expressed. PRC2 works by chemically modifying histones, which are proteins that associate intimately with DNA to regulate how it functions in the cell. The team has found that blocking PRC2 leads to the reactivation of a powerful anti-tumor pathway that can protect against AML. “Our results emphasize the idea that targeting chromatin regulators is an effective means of reawakening growth-halting mechanisms that lie dormant in most cancer cells,” says Vakoc. The study appears online in Oncogene on April 2.

AML is caused by changes not only in the genome but also the epigenome, which can be likened to a chemical instruction manual that contains reversible or rewritable instructions on how genes are expressed in cells. “If you think of the genome as something that’s hardwired, then the epigenome is something that can be rewired,” explains Vakoc. A growing body of evidence suggests that AML can arise from dysregulation of the epigenetic machinery that controls chromatin.

Using an RNA interference (RNAi) screen in which small hairpin-shaped RNA were used to systematically switch off every known chromatin regulator, Vakoc’s team, in collaboration with the lab of CSHL Adjunct Professor Scott Lowe, Ph.D., looked for signs of inhibition of the growth of leukemic cells but not normal cells. The team’s previous use of this approach identified a potent target called Brd4, a drug for which is currently in pharmaceutical development. Much of the technology for RNAi screening has been pioneered at CSHL by the laboratory of Gregory Hannon, Ph.D.

“In our new screen, PRC2 was one of the few chromatin regulators that was needed by cancer cells, but dispensable for normal blood cells,” says team member Eric Wang. Blocking PRC2 led to growth arrest of leukemic cells and their differentiation — the loss of ability to self-renew.

Although the screen also turned up other potential drug targets when performed in vitro, i.e., in cells grown in the lab, PRC2 was one of the few targets whose inhibition stopped the growth of leukemic cells in the bone marrows of mice with an aggressive form of AML. “These advanced mouse models, pioneered by former CSHL post-doctoral fellow Johannes Zuber while he was in Scott Lowe’s laboratory, have given us the ability to discriminate between unsuccessful targets that only work in plastic dishes and those that are effective inside animals,” says Vakoc.

The lack of such preclinical evaluation and validation is one reason why so many drug trials fail. The use of cancer mouse models as preclinical test-beds, as described in the current study, is a cornerstone of CSHL’s Cancer Therapeutics Initiative, which guides drug development by prioritizing drug targets that are identified by RNAi screens.

“We found that targeting the PRC2 complex allows reactivation of Ink4/Arf, genes that control a powerful potent tumor suppressor pathway that becomes silenced in AML. This provides a clear rationale for a chromatin regulator as a drug target in this disease,” says graduate student Junwei Shi, who performed these experiments.

Both cancer-causing oncogenes as well as tumor suppressor genes, which are frequently missing or inactivated in AML, are often challenging to target with small molecule inhibitors. “Epigenetic regulators such as PRC2, on the other hand, are considered druggable and therefore are good surrogate targets,” explains Vakoc. “Targeting Brd4, for example, is a great way to switch off the Myc oncogene. And as this study shows, targeting PRC2 is a great way of switching on the Ink4/Arf tumor suppressors.”

The druggability of PRC2 lies in its identity as a lysine methyltransferase, a type of protein with deep greasy pockets in its structure that are accessible to small molecule drugs that can block its activity. Lysine methyltransferase inhibitors are already being developed as candidate anticancer drugs by many pharmaceutical companies.

Founded in 1890, Cold Spring Harbor Laboratory (CSHL) has shaped contemporary biomedical research and education with programs in cancer, neuroscience, plant biology and quantitative biology. CSHL is ranked number one in the world by Thomson Reuters for impact of its research in molecular biology and genetics. The Laboratory has been home to eight Nobel Prize winners. Today, CSHL’s multidisciplinary scientific community is more than 350 scientists strong and its Meetings & Courses program hosts more than 11,000 scientists from around the world each year. Tens of thousands more benefit from the research, reviews, and ideas published in journals and books distributed internationally by CSHL Press. The Laboratory’s education arm also includes a graduate school and programs for undergraduates as well as middle and high school students and teachers. CSHL is a private, not-for-profit institution on the north shore of Long Island. For more information, visit www.cshl.edu.

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